The energy required to melt 1 g ice is 33J. The number of quanta of radiation of frequency `4.67xx10^(13) "sec"^(-1)` that must be absorbed to melt 10 g ice is

Find the number of quanta of radiations of frequency 4.67xx10^(13)s^(-1) , that must be absorbed in order to melt 5 g of ice. The energy required to melt 1 g of ice is 333J.

The number of quanta of radiation of frequncy 4.98 xx 10^(14) s^(-1) required to melt 100 g of ice are ( latent heat of melting of ice is 33 joule per g)

Calculate the energy of one moles of quanta of radiation whose frequency is 5 xx 10^(10)sec^(-1)

The latent heat of fusion of ice is 330 J//g . Calculate the number of photons of radiation of frequency 5xx10^(13) s^(-1) to cause the melting of 1 mole of ice. Take h=6.6xx10^(-34) J.S. Express your answer as X xx 10^(22) , what is the value of 'X'

Find the number of photons of radiation of frequancy 5xx10^(13)s^(-1) that must be absorbed in order to melt one g ice when the latent heat of fusion of ice is 330J//s .

The number of photons in radiation of frequency 2xx10^13 Hz and energy content 6.63 J is

Ice cubes at 0^(@)C each of mass 200 g are dropped one after the other into 2 kg water at 30^(@)C in such a awayy that after the first one melts completely, the second one is dropped. If the heat energy required to melt 1 g of ice is 80 cal, determine the maximum number of ice ice cubes that can be dropped into the water such that no ice is left in the water without melting.

Energy of an quanta of frequency 10^(15) Hz and h = 6.6 xx 10^(-34) J - sec will be